Process for manufacturing a through insulated interconnection in a body of semiconductor material

ABSTRACT

The process for manufacturing a through insulated interconnection is performed by forming, in a body of semiconductor material, a trench extending from the front (of the body for a thickness portion thereof; filling the trench with dielectric material; thinning the body starting from the rear until the trench, so as to form an insulated region surrounded by dielectric material; and forming a conductive region extending inside said insulated region between the front and the rear of the body and having a higher conductivity than the first body. The conductive region includes a metal region extending in an opening formed inside the insulated region or of a heavily doped semiconductor region, made prior to filling of the trench.

PRIORITY

This is a divisional of the prior application Ser. No. 10/406,633, filed Apr. 2, 2003 now U.S. Pat. No. 6,838,362, the benefit of the filing date of which is hereby claimed under 35 USC 120, the prior application claiming priority from European application No. 02425207.4, filed Apr. 5, 2002, under 35 USC 119. The prior patent application and the European patent application are incorporated by reference.

TECHNICAL FIELD

The present invention relates generally to a process for manufacturing a through insulated interconnection in a body of semiconductor material.

BACKGROUND OF INVENTION

As is known, for manufacturing microsystems comprising elements obtained using different technologies, such as microelectromechanical systems (MEMS) and integrated circuits, there exists the need to electrically connect two opposite faces (front and rear) of substrates integrating electronic components or, generally, carrying passive elements and/or protection structures and/or connection structures to other substrates.

EP-A-0 926 723 describes a process for forming front-rear through contacts in micro-integrated electronic devices. According to this process, a metal contact region extends through a through opening in the chip. In detail, this process is basically made up of the following steps:

-   1. Formation of metal connection regions on the front of a wafer     during formation of the contacts of the device; the metal connection     regions are formed at the location where the connection with the     rear of the wafer will be made; -   2. Etching of the rear of the wafer for partial removal of the     substrate in the connection locations with formation of openings     passing right through the wafer; -   3. Deposition of an insulating layer on the bottom and on the walls     of the through cavities; -   4. Removal of the insulating layer from the bottom of the cavity to     obtain contact areas with the front of the wafer and with the metal     connection regions; -   5. Deposition or growth from the rear of a metal layer, which coats     the walls of the cavities, makes electrical contact with the metal     connection regions, and has surface portions on the rear of the     wafer; and -   6. Formation on the rear of connection regions towards the outside     in electrical contact with the surface portions.

In the process described above, the biggest difficulties lie in insulating the through openings (deposition of oxides, nitrides or polymeric materials), in that they have a depth of several tens of microns and have substantially vertical walls.

EP-A-1 151 962 describes a structure for electrical connection between two bodies of semiconductor material obtained by digging trenches of a closed (annular) shape from the front of a first, heavily doped, wafer and filling the trenches with dielectric material. Next, the first wafer is thinned from the rear until the trenches are reached, so obtaining an insulated-silicon area (silicon plug), which connects the front and the rear of the wafer. Next, the first wafer is fixed to a second wafer which houses integrated components. If MEMS are made in the first wafer, it can be used as protection for the MEMS and their connection to the second wafer.

In the above structure, the need to dope the first wafer heavily to reduce resistance of the silicon plugs limits the applicability of this solution. In particular, in the first wafer, only some types of microsystems may be integrated, and normally the integration of active components is not possible.

SUMMARY OF THE INVENTION

An embodiment of the present invention provides a process that will enable a front-rear connection of a wafer of semiconductor material in a simple way and without limiting the type of structures that can be integrated in the wafer.

According to an embodiment of the present invention, there is, thus, provided a process for manufacturing a through insulated interconnection, as well as an integrated electronic device.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, a number of preferred embodiments will now be described, purely by way of non-limiting example, with reference to the attached drawings, in which:

FIG. 1 is a perspective cross-section of a wafer of semiconductor material during an initial fabrication step in accordance with an embodiment of the invention;

FIGS. 2 to 5 are cross-sections of the wafer of FIG. 1, in subsequent fabrication steps in accordance with an embodiment of the invention;

FIGS. 6 to 8 are cross-sections, at an enlarged scale, of a portion of the wafer of FIG. 4, in subsequent fabrication steps in accordance with an embodiment of the invention;

FIG. 9 is a cross-section of a composite wafer according to a variant of FIG. 8 in accordance with an embodiment of the invention;

FIG. 10 is a perspective cross-section of a wafer of semiconductor material, in an initial fabrication step, according to a different embodiment of the invention;

FIGS. 11 and 12 are cross-sections of the wafer of FIG. 10, in subsequent fabrication steps in accordance with an embodiment of the invention;

FIG. 13 is a cross-section of a composite wafer integrating a fingerprint sensor, obtained using the technique illustrated in FIGS. 10 to 12 in accordance with an embodiment of the invention; and

FIG. 14 illustrates a variant of FIG. 9 in accordance with an embodiment of the invention.

DETAILED DESCRIPTION

With reference to FIG. 1, a first wafer 1 comprising a substrate 4 of semiconductor material, typically monocrystalline silicon doped in a standard way, for example a P-type <100> substrate with a resistivity of 15 Ω/cm, having a first surface 7 and a second surface 5, has undergone steps for making trenches, according to what is described in the above-mentioned patent application EP-A-1 151 962 which is incorporated by reference. In particular, the first wafer 1 has been masked and etched to form deep trenches 2 having a closed shape and surrounding cylindrical regions 3 of monocrystalline silicon. The trenches 2 may have a depth of, for example, 50–100 μm.

Next (see FIG. 2), the trenches 2 are filled, either completely or partially, with insulating material 6, for example, silicon dioxide. For this purpose, a silicon dioxide layer is deposited or grown, and is then removed from the first surface 7 of the first wafer 1 to obtain the structure of FIG. 2.

In a known way (see FIG. 3), using implantation, diffusion, deposition and growth steps, inside and on the first surface 7 of the substrate 4, conductive and/or insulating regions are formed, so as to obtain electronic components 9 (schematically represented in FIG. 3) according to the circuit that is to be obtained.

In addition, the surface area of the cylindrical region 3 is doped, so as to reduce the resistivity, thus forming contact regions 8. The contact regions 8 are preferably made simultaneously with diffused areas in the substrate 4.

Next, on top of the first surface 7, insulating layers 10 and metal connection regions 11 are deposited. In the illustrated example, a connection region 11 electrically connects, via contacts 12, 13, the contact region 8 to a top surface 14 of the wafer.

Next (see FIG. 4), the first wafer 1 is bonded to a second wafer 15 comprising at least one substrate 16. The substrate 16 houses conductive and/or insulating regions, which form electronic components 20 (also represented schematically). The substrate 16 may be coated with an insulation and/or passivation layer (not illustrated) housing metal contact regions.

The bonding technique may be direct, by means of palladium/silicon bonds; alternatively, as illustrated in FIG. 4, bonding regions 18 are provided of a suitable material, for example, gold, to form a gold/silicon eutectic, as described in the above-mentioned patent application EP-A-1 151 962, or else a low-melting alloy may be used, such as gold/tin. In this way, the composite wafer 21 is obtained formed by the first wafer 1 and the second wafer 15.

Next (see FIG. 5), the first wafer 1 is thinned from the rear mechanically, for example, by grinding, until the bottom of the trenches 2 are reached, preferably until a thickness of less than 100 μm is obtained, for example. 50 μm up to 30 μm. The first wafer 1 thus has a second surface 22 opposite to the first surface 7 of the substrate 4, and the cylindrical regions 3 are now insulated from the rest of the substrate 4.

The second surface 22 is then coated with a dielectric layer 23, which is preferably deposited, for insulation of the rear (see FIG. 6).

Using a mask (not shown), the substrate 4 of the first wafer is dug to form openings 24 extending inside the cylindrical regions 3, as illustrated in the enlarged detail of FIG. 6. Preferably, the openings 24 reach the contact regions 8. If these latter regions are not present, the openings 24 may extend until they touch the first surface 7 of the substrate 4.

Next (see FIG. 7), a seed layer 25 is deposited on the rear of the first wafer 1, with the aim of favoring the subsequent galvanic growth of metal contact regions. For instance, the seed layer 25 can be obtained by dipping the composite wafer 21 in a bath of palladium, so as to get the palladium to precipitate on top of the dielectric layer 23 and on the walls and on the bottom of the openings 24, and then by depositing gold by reduction (Wet Pd+Au electroless process), or else by low-pressure chemical vapor deposition (LPCVD) of tungsten, or else by phase vapor deposition (PVD) of titanium (Ti sputtering technique).

Next, a dry resist layer (not illustrated) is deposited and shaped, to delimit the areas of the rear of the composite wafer 21 where the galvanic growth is to be obtained, and through contact regions 28 are galvanically grown. For instance, the through contact regions 28 may be made of copper or gilded nickel (Ni/Au). In particular (see FIG. 8), the through contact regions 28 grow inside the openings 24, which can be filled completely or not.

Next, the dry resist layer is removed, and the seed layer 25 is removed, where it is not covered by the through contact regions 28. In this way, the structure illustrated in FIG. 8 is obtained, which shows a through contact region 28 that enables connection of the rear of the first wafer 1 to the front of the same first wafer and with the second wafer 15, through a contact region 8, a metal connection region 11 and contacts 12, 13.

The process may continue with the formation of bumps on the rear in direct electrical contact with the through contact regions 28. The bumps, for example, of gold/tin, may be deposited in a known way using special (electroplating) machines.

The formation of a through-contact structure comprising an insulating region obtained by filling a trench with dielectric material and a metal conductive region inside the insulating region guarantees an excellent insulation (greater than 1000 V) of the conductive region with respect to the rest of the substrate, as well as high reliability.

Should it be necessary to have a greater resistance to high voltages or should there be necessary a capacitive decoupling between the through conductive region and the rest of the substrate, it is possible to provide multiple insulation structures, as illustrated in FIG. 9, wherein a second trench 2 a, also filled with dielectric material 6 a, is present outside the trench 2 and concentrically thereto. The structure of FIG. 9 may be obtained by adopting the same procedure described above, with the only difference of providing two concentric trenches 2 and 2 a simultaneously and filling both of them with dielectric material.

The illustrated structure presents extremely low resistance thanks to the use of metal and to the shortness of the connection between the front and the rear of the first wafer 1.

This embodiment of the present invention allows working the wafer from the rear, for example to form integrated components, in which the second wafer 15 (which has a normal thickness of, for example, 675 μm for a diameter of 150 mm) may in turn contain integrated components or just have a function of mechanical support during handling of the first wafer.

The operations on the rear may all be carried out at low temperature (except, possibly, for the deposition of dielectric material using the plasma-enhanced chemical vapor deposition (PECVD) technique), and consequently do not interfere with any components that may have been made on the front of the first wafer 1 or in the second wafer 15.

The presence of the contact region 8 enables complete digging of the first wafer 1 to be avoided, and hence simplifies the digging operations and reduces the brittleness of the first wafer 1 itself.

Should it be necessary to have a through-contact structure with very low resistivity, such as the one described previously, it is possible to provide, inside the insulating region 3, doped silicon connections, according to the embodiment described hereinafter.

In detail, initially, the first wafer 1 undergoes a trench etch, in a way similar to the embodiment described above. Also in this case, the first wafer 1 comprises a standard substrate 4, of any thickness and any resistivity, so as to be able to integrate standard electronic components. Consequently, at the end of the etching process, the first wafer 1 has trenches 2 surrounding cylindrical regions 3, as illustrated in FIG. 1.

Next, as shown in FIG. 10, maintaining the masking layer used for the trench etch, the wafer is doped in an oven. Given the protection of the first surface 7 of the substrate 4 through a protective layer 16 (for example, a silicon dioxide layer), the dopant species diffuse only inside the trenches 2, as indicated by the arrows in FIG. 10. Consequently, on the outer walls and on the inner walls of the trenches 2, outer annular portions 30 a and inner annular portions 30 b are formed and connected underneath the trenches 2 by bottom portions 30 c. The cylindrical regions 3 now each comprise a central region 3′, doped in a standard way, and an inner annular portion 30 b.

Next (see FIG. 11), the trenches 2 are filled with insulating material 6, in a manner similar to the above, and the structure is planarized.

Then the electronic components (not shown in FIG. 11), the insulation layers 10 on the front of the wafer, the contacts 12, 13, and the metallizations 11 are made, and the first wafer 1 is bonded to the second wafer 15. Here, each contact 12 is in electrical contact with at least the respective inner portion 30 b (in this case it may have an annular shape) or with the entire area of the cylindrical region 3 (including both the inner portion 30 b and the central region 3′).

Next (see FIG. 12), the first wafer 1 is thinned from the rear, until at least the trenches 2 are reached. In this way, the bottom portions 30 c are removed, and the outer portion 30 a and inner portion 30 b are no longer electrically connected together. In practice, each central region 3′ is now surrounded by a conductive region or via 30 b, formed by a respective inner annular portion 30 b and insulated from the rest of the first wafer 1 by the insulating material 6.

Next, the first wafer 1 undergoes further fabrication steps, which include the possible formation of components on the rear, and the formation of contacts and/or bumps on the rear.

According to the above solution, by making trenches 2 having an internal diameter of 10 μm, with a final thickness of the first wafer 1, after thinning-out, of 100 μm, the vias 30 b have a resistance R of:

${R = {{R_{\bullet}\frac{100}{2\pi\; 10}} = 1}},{6\; R_{\bullet}}$ where R_(□) is the layer resistance of the conductive regions 30 b, obtained thanks to doping. For instance, by doping the substrate 4 with POCl₃, it is possible to obtain layer resistances of less than 1 Ω/μm, and, hence, resistances R in the region of 1 to 2 Ω. By increasing the radius of the cylindrical regions 3 to a few tens of microns and by reducing the thickness of the first wafer 1 after thinning, to 50 μm, vias 30 b with a resistance of down to 100 mΩ are obtained.

The embodiment illustrated in FIGS. 10 and 11 may be used for forming a sensor for fingerprints directly on the rear of the wafer, which houses the control circuitry and processing of the signals, as shown in FIG. 13.

The device illustrated in FIG. 13 comprises a first wafer 1, which integrates the components and the electrodes necessary for operation of the sensor, and a second wafer 15, which has purely a supporting function, in order to enable handling of the first wafer 1. On the rear of the first wafer 1, the electrodes are formed. In particular, the reference number 40 designates sensing electrodes for capacitive detection of fingerprints, and the reference number 42 designates electrodes for biasing of the skin. The sensing electrodes 40 are insulated from the environment by a passivation layer 41, while the biasing electrodes 42 are not covered, so as to enable application of the necessary biasing voltages to the skin. The sensing electrodes 40 and the biasing electrodes 42 are connected to the front of the first wafer 1 through the vias 30 b, which are made in the way described with reference to FIGS. 10 to 12. The contacts 44 formed on the front connect the vias 30 b to the integrated components designated as a whole by 43. The integrated components 43 are made on the front of the first wafer 1 and comprise diffused regions 45.

The front of the first wafer 1 is covered by an insulation and protection region 46, on top of which there is formed an adhesive region 47 and contact pads 48.

The second wafer 15 is bonded to the first wafer 1 at the adhesive region 47, and has cavities 50 facing the first wafer 1 at the contact pads 48. The cavities 50 are formed prior to bonding of the wafers 1, 15 on the front of the second wafer 15.

FIG. 13 also shows scribing lines 55, along which, using a diamond blade, the wafer is cut to obtain a plurality of sensors. The portions of the second wafer 15 on top of the cavities 50 are further removed at the lines 56, for example, by reactive ion etching (RIE) to form a trench etch, so as to enable access to the contact pads 48.

In practice, the through contact structure according to FIGS. 10 to 13 comprises, in a way similar to the embodiment illustrated in FIGS. 1 to 9, an insulating region 6, obtained by filling a trench with dielectric material, and a conductive region 30 b, formed inside the insulating region. In this case, unlike the first embodiment, the conductive region is formed by a via made of heavily doped semiconductor material. Also in this case, an excellent insulation of the via from the rest of the substrate, as well as high reliability, is obtained, and in the case where an even higher breakdown voltage is required, it is possible to make a double insulation of the type illustrated in FIG. 9. For this purpose, using an additional mask, two mutually concentric trenches 2, 2 a are made, and doping is performed in the oven in only the more internal trench (FIG. 14).

Finally, numerous modifications and variations may be made to the process and device described and illustrated herein, all falling within the scope of the invention, as defined in the attached claims. For instance, it is possible to repeat the described steps, bonding the composite wafer 21 to a third wafer, in which the trenches have already been formed and filled and in which the electronic components and the corresponding connections have already been made, then thinning the third wafer and making the through conductive regions before or after bonding and thinning. By repeating the above operations even a number of times, it is possible to make a stack of wafers piled on top of one another and connected together by conductive regions that are insulated from the rest of the respective wafer and have a much lower conductivity than that of the respective wafer.

Furthermore, an integrated circuit, such as a finger-print detector, that includes one of the above-described via structures may be included in an electronic system, such as a finger-print detection system. 

1. An integrated circuit, comprising: a first substrate having a first resistivity and first and second opposite surfaces; at least one conductive through region disposed in the first substrate between the first and second surfaces and having a second resistivity that is less than the first resistivity; and a first insulator region disposed in the first substrate between the first and second surfaces and completely surrounding the conductive through region.
 2. The integrated circuit of claim 1, further comprising: a second substrate attached to the first surface of the first substrate; and a contact region disposed in the second substrate and in electrical contact with the conductive through region.
 3. The integrated circuit of claim 1 wherein the conductive through region comprises: a doped semiconductor contact region that extends to the first surface; and a metal region in contact with the semiconductor contact region, extending to the second surface, but not extending to the first surface.
 4. The integrated circuit of claim 1 wherein the conductive through region comprises: a first silicon region contiguous with the first insulator region and having a doping concentration; and a second silicon region completely surrounded by the first silicon region and having a doping concentration that is less than the doping concentration of the first silicon region.
 5. The integrated circuit of claim 1, further comprising: wherein the first insulator region is substantially annular; and a substantially annular second insulator region disposed in the first substrate between the first and second surfaces and completely surrounding the first insulator region.
 6. The integrated circuit of claim 1 wherein the first insulator is substantially annular.
 7. The integrated circuit of claim 1 wherein the conductive through region includes a semiconductor region that extends between the first and second surfaces of the first substrate and is substantially uniformly doped between the first and second surfaces of the first substrate.
 8. An electronic system, comprising: an integrated circuit, including, a first substrate having a first conductivity and first and second opposite surfaces, at least one conductive through region disposed in the first substrate between the first and second surfaces and having a second conductivity that is greater than the first conductivity, and a first insulator region disposed in the first substrate between the first and second surfaces and completely surrounding the conductive through region.
 9. An integrated electronic device, comprising: a first body of semiconductor material having a first face and a second face; a first trench extending through said first body between said first and said second faces, the first trench defining and completely surrounding a through region; and a first dielectric material filling said first trench, said dielectric material electrically insulating said through region from the rest of said first body; and wherein said through region includes a conductive region having a higher conductivity than said first body and extending between said first face and said second face.
 10. The device according to claim 9, wherein said first body has a resistivity of between 1 Ω/cm and 100 Ω/cm.
 11. The device according to claim 9, further comprising at least one further trench completely surrounding said first trench and filled with insulating material.
 12. The device according to claim 9, comprising a second body bonded to said first face of said first body.
 13. The device according to claim 9, wherein said first body houses integrated electronic components facing one another and/or extending above said first face.
 14. The device according to claim 9, wherein said conductive region comprises a contact region of metal material.
 15. The device according to claim 14 wherein the conductive region comprises a semiconductor region facing said first face, said semiconductor region having a higher doping level than said first body and being in direct electrical contact with said contact region of metal material and with electrical-connection regions formed on top of the first face, said contact region of metal material separated from the electrical-connection regions.
 16. The device according to claim 9, wherein said conductive region comprises a contact region of semiconductor material having a higher doping level than said first body.
 17. The device according to claim 16, wherein said conductive region is contiguous to said dielectric material.
 18. The device according to claim 9 wherein the through region is substantially cylindrical.
 19. The device according to claim 9, further comprising: wherein the through region is substantially cylindrical; a substantially annular second trench completely surrounding the first trench; and a second dielectric material filling said second trench.
 20. The device according to claim 9 wherein: the conductive region comprises a first semiconductor region that is contiguous to the first dielectric material and that has a higher doping concentration than the first body; and the through region further includes a second semiconductor region that is completely surrounded by the conductive region and that has a lower doping concentration than the first semiconductor region. 